DE102006014691B3 - Opposite polarity electrode plates separator for lead-acid storage battery, has base material thickness of separator sheets at exterior edge of border area, where thickness of electrode plate increases in contact area of separator - Google Patents

Abstract

The separator has a base material thickness of separator sheets (1) at an exterior edge of a border area (R). The thickness of an electrode plate increases in a contact area (A) of the separator sheet. The base material thickness of an electrode plate in the border area adjacent to the contact area is larger than the base material thickness of the contact area. A projecting rib (2a) is arranged over the base material thickness in the border area. An independent claim is also included for a lead-acid battery with separators having one electrode from alternatively arranged positive and negative flat shaped electrodes, which are arranged between the separators for the separation of the opposite polarity electrodes.

Description

The The invention relates to a lead-acid battery with at least one electrode set of alternately arranged positive and negative plate-shaped electrodes, between which separators for separating the opposing electrodes are arranged, wherein the separators each of two separator sheets by Joining of on adjacent edge regions of the separator sheets on one side for inserting an electrode plate open pockets are formed.

The The invention further relates to a separator for separating gegenpoliger Electrode plates of such a lead-acid battery with two separator sheets, the to an open on one side for insertion of an electrode plate Bag connected to each other on adjacent edge regions are.

separators are known in accumulators, electrode plates of opposite polarity from each other electrically disconnect, leaving an electrically conductive path between each two electrodes forms over the electrolyte.

In Lead-acid accumulators the typical separator is a porous diaphragm with parallel running ribs on a surface. Regularly, the ribs on the mounted positive plate adjacent, leaving the negative plate a smooth side faces. However, it is also possible, even the to provide the negative plate facing side with ribs or reverse the assembly. It is known separators form in the form of an open-topped pocket by a Separatorenblatt is made, the one the height slightly higher than two separators Length. The Leaf is halfway up folded against each other and the side areas become, for example, each other welded, so that the open top pocket forms.

Out EP 0 541 124 B1 For example, a separator of the type mentioned in the opening paragraph is known, which pocket-like manner is formed inwardly with inwardly directed ribs in order to receive a positive electrode plate. The ribs in the middle region of the separator run vertically and parallel to one another. The ribs in the side edge region consist of short, mutually parallel rib sections which extend horizontally or obliquely to vertical ribs in the middle region. The second ribs arranged in the edge region have a smaller rib height than the first ribs arranged in the middle region and serve to rest against the edges of the positive electrode plate inserted in the pocket.

EP 0 994 518 B1 also discloses a bag-shaped separator whose ribs face towards the outside of the bag. In the middle region vertical ribs are formed, while the side edge regions have a plurality of smaller ribs. The ribs formed with a square or rectangular cross-section serve to reduce the bearing surface of the separator, in particular on the positive electrode plate, since oxygen can be formed there, which would corrode a planar-fitting separator material. The ribs in the central region and in the side wall region are therefore designed so that gases which form can escape to the open-top side of the accumulator.

The Need ribs have a certain stability, resulting in a certain minimum width. The separators should further be formed so that the electrode plates relative to the separators, in particular pocket-shaped separators, are laterally displaceable to the alignment of the electrode plates to enable.

US 5,558,952 discloses a pocket separator, the two layers, which are connected to each other at two opposite edges, parallel to the two edges extending central ribs. At the edge of the separator are located at both layers inclined ribs whose height decreases relative to the respective position from the inside out. The ribs are located in the inclined portion of the separator pocket, so that they extend with a relatively far-lying area diagonally to the edge of a plugged into the separator pocket plate electrodes. The decrease in the height of the rib to the outside is due to the joining of the two layers by the edge regions, whereby the ribs of the two layers in cross section obliquely to each other.

The Basic material thickness the separator sheet is constant. The connection on top of each other margins takes place adjacent to the sloping, inclined ribs.

US Patent 6,001,503 discloses bag-shaped Separators for Lead-acid batteries, the one with a variety closely adjacent lying ribs low height have provided edge area. Two adjoining Separatorenblätter be in the outer area interconnected, the separator sheets are pulled together and with the side edge of a pocketed electrode plate in Contact us.

US Pat. No. 6,410,183 B2 discloses a battery separator for lead-acid batteries which has a plurality of additional small ribs in the shoulder regions to increase puncture resistance which two adjoining Separatorenblätter are joined together.

A similar embodiment shows WO 2005/015661 A1. The additional ribs on the edge areas are sawtooth.

Furthermore, from the DE 102 52 674 B4 a separator is known, in which in the edge region next to a number of first ribs further ribs are provided with a rising rib profile, which abut in the symmetrically adjusted state of the adjacent electrode on the surface of the electrode with a formed at the highest point of the rise of the rib profile line-shaped edge.

US 963,284 A discloses a separator for accumulators with ribs and edge regions of equal thickness as the ribs.

The Problem of the conventional pouched Separators is that the electrode plates at the edge areas after joining each other lying separator sheets be clamped there. The electrode plates can then no longer be easily aligned and the risk of puncturing the Separators through the sharp edges of the electrode plates is elevated.

task It is therefore an improved separator of the present invention and to provide a lead-acid battery containing a separator, where the puncture resistance, the availability of Edge regions of successive separator sheets and the displaceability the electrode plates is improved.

The The object is achieved by the separator of the type mentioned in the present invention solved, that the base material thickness the separator sheets at the edge areas of the outer edge of a Edge area in direct direction to the contact area of the separator sheet for one Electrode plate increases and adjacent the base material thickness in the edge region to the investment area larger than the Base material thickness of the investment area.

in the Difference to the conventional ones Solutions, in which at the edge areas, if necessary, the geometry by additional Ribs changed is now proposed, the basic material thickness of Separatorenblatts even at the edge areas to enlarge. It Thus, a step between the contact area for an electrode plate and formed the adjacent edge region. This level prevents ver a clamping of the electrode plate in the Separatorenblättern and leads to this can be better aligned. The material accumulation in the Edge area leads to a significant increase the puncture resistance the separators. Due to the fact that the base material strength in the edge area from the investment area to the outside decreases again, d. H. Wedge-shaped in cross-section is also achieved. material stress is removed from the edges of eingetaschter electrode plates.

Advantageous it is when at least in the border area adjacent to the investment area one over the base material thickness protruding rib is arranged. With the help of this at least a rib in the edge area, the alignment and adjustment eingetaschter Electrode plates supported become. Furthermore is the surface The edge areas smooth, to a stable and easy joining each other lying separator sheets to ensure.

Farther It is advantageous if in the usual way in the investment area for an electrode plate a plurality of over the base material thickness of the contact area protruding ribs are provided.

there can the separators selected main ribs for positioning an electrode plate with one to side ribs have larger rib height.

The Separator pockets can be formed so that the ribs face outward and negative electrode plates be added to the inside smooth separator bag. Especially advantageous However, it is when ribs in the interior of the separator bag available and positive electrode plates are dipped in.

The flat superposed in cross-section wedge-shaped edge areas associated separator leaves can glued together, welded or to form a bag be knurled. Any other suitable joining methods are alike conceivable.

The Task is further with a separator of the aforementioned Kind solved by that the basic material thickness the separator sheets the edge areas of the outer edge an edge region in the direction of the contact area of the separator sheet for one Electrode plate increases and adjacent the base material thickness in the edge region to the investment area greater than the basic material thickness of the investment area.

advantageous embodiments are in the subclaims described.

The Invention is based on an embodiment with the attached Drawings closer explained. Show it:

1 - Cross-sectional view of a separator sheet with ribs and wedge-shaped edge regions of increased base material thickness;

2 - Cross-sectional view of a peripheral region of the separator sheet off 1 ;

3 - Sectional cross-sectional view of adjacent to the edge region bearing area of the separator sheet 1 ,

The 1 leaves a cross-sectional view of a separator sheet 1 recognize that has a contact area A for an electrode plate (not shown) and edge portions R at the side edges. In area A are main and secondary ribs 2a . 2 B provided in a conventional manner.

The edge regions R have a width B _R and have a mean base material thickness D _R greater than the base material thickness of the separator sheet 1 (not including the ribs) of the investment area A is.

The 2 leaves in the 1 sketched left edge area R in enlarged view in detail. It is clear that the basic material thickness D _R2 (without taking into account the main rib 2a ) is greater than the base material thickness D _{A of} the contact area in the boundary region between edge region R and contact region A. Furthermore, it can be seen that the edge region R is tapered outward in a wedge shape by the base material thickness D _{R1 of} the separator sheet 1 at the edge region R from the outer edge of the edge region R in the (direct) direction to the abutment region A of the Separtorenblatts 1 increases to the base material thickness D _R2 , which is greater than the base material thickness D _R1 at the outer edge.

By the wedge-shaped rejuvenation the edge areas is achieved that a material tension on the Edges of eingetaschter electrode plates is reduced.

It is further clear that the edge regions R have no ribs and have a smooth surface, so that the edge regions R adjoining one another to a pocket Separatorenblätter 1 lie flat on each other. This also improves the availability of the associated separator sheets, for example by gluing, welding, such. B. ultrasonic welding, knurling etc ..

Due to the increased base material thickness D _{R2 of} the edge region R adjacent to the abutment region A in comparison to the base material thickness D _{A of} the abutment region A and the associated material accumulation, the puncture resistance of the separator pockets is improved.

The 3 leaves a section of the separator sheet 1 in the region of the contact section A in cross section. It becomes clear that the main ribs 2a in the transition to the edge region R have a first radius R1, which preferably corresponds to the radius R3 in the transition to the contact area A, but may also be different. The radius R1 and R3 may be, for example, 0.3 mm.

The radius R2 of the curvature of the main ribs 2a is much smaller than the transition radii R1 and R3 and is for example 0.15 mm.

Furthermore, it can be seen that between the main ribs 2a . 2 B a number of, for example, three minor ribs 2 B are arranged, extending in the longitudinal direction of the separator sheet 1 extend. It is clear that the head radius R4 of the side ribs 2 B significantly larger than the head radius R2 of the main ribs 2a is, for example, 0.3 mm, ie twice as large as the head radius R2 of the main ribs 2a is. Furthermore, it is clear that the transition radii R5 of the secondary ribs 2 B to the separator sheet 1 smaller than the transition radii R1 and R3 of the main ribs 2a are. For example, the transition radius R5 is 0.2 mm.

The height D _{N of} the side ribs 2 B is less than the height D _{H of} the main ribs. Preferably, the ratio between the height D _{H of} the main ribs to D _{N of} the height of the side ribs 2a about 2.5. In a preferred embodiment, the height D _{H is} 1.5 mm and the height of the D _{N of} the side ribs 2 B 0.6 mm. The basic material thickness D _A of the separator 1 is in this respect still much lower and is preferably in the range of 0.2 to 0.1 mm, 0.15 mm. The ratio between height D _N of sub-rib 2 B and base material thickness D _{A of} the separator sheet 1 is preferably in the range between 3 and 5 and is preferably about 4.

It can also be seen that over the area in the transverse direction in the intermediate space Z between two successive main ribs 2a a relatively small number of three minor ribs 2 B are provided. Compared to conventional ribs is the accumulation of material through the side ribs 2 B with the help of the relatively high height D _{N of} the side ribs 2 B and compared to conventional side ribs relatively large width or relatively large head radius R4 so strong that a relatively high rigidity of the separator sheet 1 is achieved in the longitudinal direction. This has the advantage that the working cycle for the production of separator pockets and for embedding the electrode plates in the separator pockets, by folding up and joining the separator sheets 1 can be formed at the edge regions R, can be increased.

From the 3 is still recognizable that the main ribs 2a are inclined at an angle α of, for example, about 9 °. By this angle of inclination is achieved that on the main ribs 2a lying electrode plates can move sufficiently easily and on the other side a wave formation of the separator sheets 1 together is avoided. The waves form the relatively broad side ribs 2 B also contrary.

Claims (12)

Separator for separating opposing electrode plates of a lead-acid battery with two separator blades ( 1 ), which are connected to each other at marginal regions (R) to a pocket open on one side for insertion of an electrode plate, characterized in that the base material thickness (D _R ) of the separator sheets ( 1 ) at the edge regions (R) from the outer edge of an edge region (R) in the direction of the abutment region (A) of the separator sheet ( 1 ) increases for an electrode plate and the base material thickness (D _R2 ) in the edge region (R) adjacent to the contact area (A) is greater than the base material thickness (D _A ) of the contact area (A). Separator according to claim 1, characterized in that in the edge region (R) adjacent to the abutment region (A) at least one over the base material thickness (D _R2 ) protruding rib ( 2a ) is arranged. Separator according to claim 1 or 2, characterized in that in the contact area (A) a plurality of over the base material thickness (D _A ) of the contact area (A) protruding ribs ( 2a . 2 B ) are provided. Separator according to claim 1 or 2, characterized in that selected main ribs ( 2a ) for positioning an electrode plate having a ridge height (D _N ) of side ribs ( 2 B ) Greater rib height (D _H) have. Separator according to one of claims 1 to 4, characterized in that the flat superposed in cross section wedge-shaped edge regions (R) associated separator sheets ( 1 ) are glued together, welded or knurled to form a bag. Separator according to one of claims 2 to 5, characterized in that the ribs ( 2a . 2 B ) are arranged in the interior of the bag. Lead-acid battery containing separators according to one of the preceding claims, having at least one electrode set of alternately arranged positive and negative plate-shaped electrodes, which are arranged between the separators for the separation of the antipolar electrodes, the separators in each case from two separator sheets ( 1 ) by joining superimposed edge regions (R) of separator sheets ( 1 ) are formed to open on one side for insertion of an electrode plate pockets, characterized in that the base material thickness (D _R ) of the separator sheets ( 1 ) at the edge regions (R) from the outer edge of a peripheral region (R) in the direction of the abutment region (A) of the separator ( 1 ) increases for an electrode plate and the base material thickness (D _R2 ) in the edge region (R) adjacent to the abutment region (A) is greater than the base material thickness (D _N ) of the abutment region (A). Lead accumulator according to claim 7, characterized in that in the edge region (R) adjacent to the abutment region (A) at least one beyond the base material thickness (D _R2 ) protruding rib ( 2a ) is arranged. Lead accumulator according to claim 7 or 8, characterized in that in the abutment region (A) a plurality of over the base material thickness (D _A ) of the contact area projecting ribs ( 2a . 2 B ) are provided. Lead accumulator according to claim 8 or 9, characterized in that the separators selected main ribs ( 2a ) for positioning an electrode plate having a rib height (D _N ) of side ribs ( 2 B ) have greater rib height (D _H ). Lead accumulator according to one of claims 8 to 10, characterized in that the ribs ( 2a . 2 B ) are arranged in the interior of the bag. Lead accumulator according to one of the preceding claims, characterized in that the flat superposed in cross-section wedge-shaped edge regions (R) associated separator sheets ( 1 ) are glued together, welded or knurled to form a bag.